1 / 68

Aliphatic Hydrocarbon: Fundamentals of Organic Chemistry CHEM 109

This chapter covers the basics of aliphatic hydrocarbons, which are organic compounds containing only carbon and hydrogen. It includes an overview of saturated and unsaturated hydrocarbons, as well as nomenclature rules for alkanes. Suitable for students of health colleges.

hucks
Télécharger la présentation

Aliphatic Hydrocarbon: Fundamentals of Organic Chemistry CHEM 109

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. CHAPTER 2. ALIPHATIC HYDROCARBON Fundamentals of Organic Chemistry CHEM 109 For Students of Health Colleges Credit hrs.: (2+1) King Saud University College of Science, Chemistry Department CHEM 109

  2. Hydrocarbons • Hydrocarbonsare Organic Compounds, which contain only the two elements carbonandhydrogen. • Aliphatic hydrocarbonsare subdivided into: • Saturated hydrocarbons • Alkanes; CnH2n+2(contain carbon-carbon single bond) • Cycloalkanes: CnH2n (contain carbon-carbon single bond in a single ring) Alkanes and cycloalkanes are so similar that many of their properties can be considered side by side. • Unsaturated hydrocarbons • Alkenes : CnH2n (contain carbon-carbon double bond) • Alkynes : Cn H2n-2 (contain carbon-carbon triple bond)

  3. Hydrocarbons Single ring Fused ring Conjoined benzene ring

  4. Saturated Hydrocarbons 1. Alkanes • General formula is CnH2n+2 Names, Molecular formulas and Number of Isomers of the first ten Alkanes • In alkanes, the four sp3 orbitals of carbon repel each other into a tetrahedral arrangement with bond angles of 109.5º like in CH4. • Each sp3 orbital in carbon overlaps with the 1s orbital of a hydrogen atom to form a C-H bond.

  5. Saturated Hydrocarbons 1. Alkanes Classes of Carbons and Hydrogen • A primary (1) carbonis one that is bonded to only one other carbon. • A secondary (2) carbonis one that is bonded to two other carbons. • A tertiary (3) carbonis one that is bonded to three other carbons. • Hydrogens are also referred to as 1, 2, or 3according to the type of carbon they are bonded to.

  6. Alkyl Group Nomenclature • An alkyl group is formed by loss of a hydrogen atom from the corresponding alkane. • General formula CnH2n+1. • The letter Ris used as a general symbol for an alkyl group. • An alkyl group is named by replacing the suffix –aneof the parent alkane by –yl. i.e. Alkane – ane + yl = Alkyl

  7. Alkyl Group Nomenclature • Examples: • Derived from methane by removing one of the hydrogens, a one-carbon substituent is called a methyl group. • Thus the two-carbon alkyl group is called the ethyl group, from ethane.

  8. Alkyl Group Nomenclature • When we come to propane, there are two possible alkyl groups, depending on which type of hydrogen is removed. • If a terminal hydrogen is removed, the group is called a propyl group. • If a hydrogen is removed from the central carbon atom, we get a different isomeric propyl group, called the isopropyl group.

  9. Alkyl Group Nomenclature • For four-carbon alkyl group, there are four different butyl groups. • The butyl and sec-butyl groups are based on n-butane. • The isobutyl and tert-butyl groups come from isobutane. n-butane

  10. Saturated Hydrocarbons 1. Alkanes Nomenclature; IUPAC Rules • The older unsystematic names, (Common names). • The IUPAC names. International Union of Pure & Applied Chemistry The IUPAC Rules 1) Select the parent structure; the longest continuous chain not X Ethylhexane Propylpentane The longest continuous chain is not necessarily straight.

  11. Saturated Hydrocarbons 1. Alkanes Nomenclature; IUPAC Rules 2) Number the carbons in the parent chain starting from the end which gives the lowest number for the substituent 1 2 4 6 5 3 4 3 not 5 2 6 1 X 3- Ethyl hexane 4- Ethyl hexane

  12. Saturated Hydrocarbons 1. Alkanes Nomenclature; IUPAC Rules 2) Number the carbons in the parent chain 2-Methylhexane To name the compound; 1) The position of the substituent on the parent carbon chain by a number. 2) The number is followed by a hyphen (-). 3) The combined name of the substituent (ethyl). 4) The parent carbon chain (hexane) - 3 Ethyl hexane

  13. Saturated Hydrocarbons 1. Alkanes Nomenclature; IUPAC Rules 3) If the same alkyl substituent occurs more than once on the parent carbon chain, the prefixes di-, tri-, tetra-, penta-, and so on are used to indicate two, three, four, five, and so on. 3 1 5 2 4 pentane 2,2,4- Tri methyl

  14. Saturated Hydrocarbons 1. Alkanes Nomenclature; IUPAC Rules 4) If different alkyl substituents are attached on the parent carbon chain, they are named in order of alphabetical order. 8 1 2 7 6 4 3 5 3,3- di ethyl methyl 4- propyl 5- octane 4 - methyl - - propyl 3,3- Diethyl - 5 Note that • Each substituent is given a number corresponding to its location on the longest chain. • The substituent groups are listed alphabetically.

  15. Saturated Hydrocarbons 1. Alkanes Nomenclature; IUPAC Rules 5) When two substituent are present on the same carbon, use the number twice. 6) When two chains of equal length compete for selection as the parent chain, choose the chain with the greater number of substituents.

  16. Saturated Hydrocarbons 1. Alkanes Nomenclature; IUPAC Rules 7) If substituents other than alky groups are also presents on the parent carbon chain; all substituents are named alphabetically. 1 4 3 5 2 chloro 2- bromo 3- 4- methyl 3- bromo - chloro - pentane 2- 4- methyl

  17. Saturated Hydrocarbons 1. Alkanes Nomenclature; IUPAC Rules Examples

  18. Saturated Hydrocarbons 1. Alkanes Nomenclature of Cycloalkanes • Cycloalkanes are saturated hydrocarbons that have at least one ring of carbon atoms. • Cycloalkanes are named by placing the prefix cyclo- before the alkane name that corresponds to the number of carbon atoms in the ring. • If only one substituent is present, no number is needed to locate it. • If there are several substituents, numbers are required. • With different substituents, the one with highest alphabetic priority is located at carbon 1.

  19. Saturated Hydrocarbons 1. Alkanes Nomenclature of Cycloalkanes • If there are more than two substituents on the ring, they are cited in alphabetical order. • The substituent given the number 1 position is the one that results in a second substituent getting as low a number as possible. • If two substituents have the same low number, the ring is numbered in the direction that gives the third substituent the lowest possible number. • Examples,

  20. Aliphatic Hydrocarbons Physical Properties of Alkanes, Alkenes and Alkynes Those properties that can be observed without the compound undergoing a chemical reaction. A. Physical States C1 (C2) to C4 are gases, C5 to C17 are liquids, C18 and larger alkanes are wax –like solids. B. Solubility • Alkanes, Alkenes and Alkynes are nonpolar compounds. • Their solubility “ Like dissolve like” • Alkanes, Alkenes and Alkynes are soluble in the nonpolar solvents; carbon tetrachloride, CCl4 and benzene, • Alkanes, Alkenes and Alkynes are insoluble in polar solvents like water. 20

  21. Aliphatic Hydrocarbons Physical Properties of Alkanes, Alkenes and Alkynes • Boiling Points & Melting Points • Effect of Molecular Weight The boiling points and melting points of normal hydrocarbons increase with increasing molecular weight. As the molecules become larger, there are more forces of attraction between them, and more energy is needed. • Effect of Branching • Among isomers, straight chain compound has the highest boiling point. • The greater the number of branches, the lower the boiling point.

  22. Saturated Hydrocarbons 1. Alkanes Preparation of Alkanes 1. Hydrogenation of unsaturated hydrocarbon: 2. Hydrolysis of Grignard reagent 3. Reduction of Alkyl halides By lithium dialkylcuprate

  23. Saturated Hydrocarbons 1. Alkanes Reactions of Alkanes Saturated hydrocarbons undergo very few reactions, so they are called Paraffinic hydrocarbons. (Latin parum, little; affinis, affinity) Combustion Halogenation The halogenation of an alkane appears to be a simple free radical substitution in which a C-H bond is broken and a new C-X bond is formed 23

  24. Saturated Hydrocarbons 1. Alkanes Reactions of Alkanes A. Halogenation • Substitution reaction of alkanes, i.e. replacement of hydrogen by halogen, usually chlorine or bromine, giving alkyl chloride or alkyl bromide. • Flourine reacts explosively with alkanes It is unsuitable reagent for the preparation of the alkyl flourides. • Iodine is too unreactive It is not used in the halogentaion of alkanes. • Halogenation of alkanes take place at high temperatures or under the influence of ultraviolet light

  25. Saturated Hydrocarbons 1. Alkanes Reactions of Alkanes A) Halogenation • Chlorination of an alkane usually gives a mixture of products • With longer chain alkanes, mixtures of products may be obtained even at the first step. For example, with propane,

  26. 2. ALKENES

  27. Unsaturated Hydrocarbons 1. Alkenes The Structure of Alkenes • Alkenesare hydrocarbons that contain a carbon–carbon double bond. • Alkenes are also Olefins. • General formula is CnH2n • The simplest members of the Alkenesseries are C2 & C3 • Hybridization; sp2-hybridized orbitals • The angle between them is 120° and bond length C=C (1.34 Å). • A trigonal planar.

  28. Unsaturated Hydrocarbons 1. Alkenes Nomenclature; Common Names • The simplest members of the alkene and alkyne series are frequently referred to by their older common names, ethylene, acetylene, and propylene. • Two important groups also have common names; They are the vinyl and allylgroups. • These groups are used in common names.

  29. Unsaturated Hydrocarbons 1. Alkenes Nomenclature; IUPAC Rules The IUPAC rules for naming alkenes are similar to those for alkanes, but a few rules must be added for naming and locating the multiple bonds. 1. The ending -ene is used to designate a carbon–carbon double bond. 2. Select the longest chain that includes both carbons of the double bond. 3. Number the chain from the end nearest the double bondso that the carbon atoms in that bond have the lowest possible numbers.

  30. Unsaturated Hydrocarbons 1. Alkenes Nomenclature; IUPAC Rules If the multiple bond is equidistant from both ends of the chain, number the chain from the end nearest the first branch point. 4. Indicate the position of the multiple bond using the lower numbered carbon atom of that bond.

  31. Unsaturated Hydrocarbons 1. Alkenes Nomenclature; IUPAC Rules NOTES The root of the name (eth- or prop-) tells us the number of carbons, and the ending (-ane, -ene, or -yne) tells us whether the bonds are single, double, or triple. No number is necessary in these cases, because in each instance, only one structure is possible. With four carbons, a number is necessary to locate the double bond.

  32. Unsaturated Hydrocarbons 1. Alkenes Nomenclature; IUPAC Rules • Branches are named in the usual way.

  33. Unsaturated Hydrocarbons 1. Alkenes Nomenclature; IUPAC Rules Example: Write the structural formula of 4-Isopropyl-3,5-dimethyl-2-octene. 1) The parent carbon chain is an Octene. The double bond is located between the 2nd and 3rd carbons. 2) Two methyl groups are attached on the parent carbon chain, one on carbon 3and the other oncarbon 5. 3) An isopropyl group is attached on carbon 4. 4) Put the missing hydrogens to get the correct structure.

  34. Unsaturated Hydrocarbons 1. Alkenes Nomenclature of Cycloalkenes • We start numbering the ring with the carbons of the double bond. • A number is not needed to denote the position of the functional group, because the ring is always numbered so that the double bond is between carbons 1 and 2. • Put the lowest substituent number into the name not in the direction that gives the lowest sum of the substituent numbers.

  35. Isomerism • Isomersare different compounds with identical molecular formulas. • The phenomenon is called isomerism. Types of Isomerism Structural Isomerism Geometrical Isomerism Alkanes Alkenes   Cycloalkanes

  36. Isomerism Structural Isomerism in Alkanes • Structural or constitutional isomers are isomers which differ in the sequence of atoms bonded to each other. • Examples: • Butanes, C4H10 • Pentanes, C5H12

  37. Isomerism Geometric Isomerism in Alkenes • In alkenes, geometric isomerism is due to restricted rotation about the carbon - carbon double bond. A) when W differs from X and Y from Z, Alkenes exist as geometric isomers • cis isomer; when two similar groups are on the same side of the double bond. • trans isomer; when two similar groups are on the opposite sides of the double bond. • They have different physical properties and can be separated by fractional crystallization or distillation.

  38. Isomerism Geometric Isomerism in Alkenes B) If (W = X or Y = Z), geometric isomerism is not possible.

  39. Isomerism Geometric Isomerism in Alkenes • For alkenes with four different substituent such as Another system, the E, Z system, • Basically, the E,Z system works as follows; Arrange the groups on each carbon of the C=C bond in order of priority • The priority depends on atomic number: The higher the atomic number of the atom directly attached to the double-bonded carbon, the higher the priority. Thus, in structure (I), Cl > F, and CH3 > H.

  40. Isomerism Geometric Isomerism in Alkenes • If the two groups of higher priority are on the same side of the C=C plane, The isomer is labeled Z;(from the German zusammen, together). • If the two groups of higher priority are on opposite sides of the C=C plane, The isomer is labeled E;(from the German entgegen, opposite).

  41. Isomerism Geometric Isomerism in Cycloalkanes cis-trans Isomerism in Cycloalkanes cis–trans isomerism (sometimes called geometric isomerism) is one kind of stereoisomerism.

  42. Preparation of Unsaturated hydrocarbons • Unsaturated hydrocarbons are prepared by Eliminationof an atom or group of atoms from adjacent carbons to form carbon-carbon double or triple bond.

  43. Preparation of Unsaturated hydrocarbons (Alkenes) 1) Dehydration of Alcohols • When an alcohol is heated in the presence of a mineral acid catalyst, It readily loses a molecule of water to give an alkene. The acid catalysts most commonly used are mineral acids as sulfuric acid, H2S04, and phosphoric acid, H3P04. • Removal of OH group and a proton from two adjacent carbon atoms using mineral acids.

  44. Preparation of Unsaturated hydrocarbons (Alkenes) 1) Dehydration of Alcohols Which Alkene Predominates?; Saytzeff’s Rule The loss of water from adjacent carbon atoms, can give rise to more than one alkene. Example: the dehydration of 2-butanol. 2-butene is the major (with two alkyl substituents attached to C=C) Saytzeff’s Rule applies In every instance in which more than one Alkene can be formed The major product is always the alkene with the most alkyl substituents attached on the double-bonded carbons.

  45. Preparation of Unsaturated hydrocarbons (Alkenes) 1) Dehydration of Alcohols • Classes of Carbocations according to the number of carbon atoms attached to the positively charged carbon. • Generally 1. The dehydration of alcohols requires an acid catalyst. 2. The predominant alkene formed follows Saytzeffs rule. 3. The reaction proceeds via a carbocation intermediate. 4. The stabilities of carbocations and the ease of dehydration of alcohols follows the order 3° > 2° > 1°.

  46. Preparation of Unsaturated hydrocarbons (Alkenes) 2) Dehydrohalogenation of Alkyl Halides • Alkenes can also be prepared under alkaline conditions. heating an alkyl halide with a solution of KOH or NaOH in alcohol, yields an alkene. 3) Dehalogenation of Vicinal Dibromides

  47. Reactions of Unsaturated hydrocarbons (1) Electrophilic Addition Reactions Addition of Symmetric and Unsymmetric Reagents to symmetric Alkenes. 1. Addition of Hydrogen: Catalytic Hydrogenation 2. Addition of Halogens: Halogenation Addition of Unsymmetric Reagents to Unsymmetric Alkenes; Markovnikov’s Rule. 1. Addition of Hydrogen Halides 2. Addition of Sulfuric Acid 3. Addition of Water: Hydration 4. Addition of HOX: Halohydrin Formation (2) Oxidation Reactions 1. Ozonolysis 2. Oxidation Using KMnO4

  48. Reactions of Unsaturated hydrocarbons (Alkenes) Electrophilic Addition Reactions 1. Addition of Hydrogen: Hydrogenation Addition of a mole of hydrogen to carbon-carbon double bond of Alkenes in the presence of suitable catalysts to give an Alkane.

  49. Reactions of Unsaturated hydrocarbons (Alkenes) Electrophilic Addition Reactions 2. Addition of Halogen: Halogenation When an alkene is treated at room temperature with a solution of bromine or chlorine in carbon tetrachloride to give the corresponding vicinal dihalide(two halogens attached to adjacent carbons)

  50. Reactions of Unsaturated hydrocarbons (Alkenes) Electrophilic Addition Reactions 3. Addition of Acids • A variety of acids add to the double bond of alkenes. The hydrogen ion (or proton) adds to one carbon of the double bond, and the remainder of the acid becomes connected to the other carbon. • Acids that add in this way are the hydrogen halides (H-F, H-Cl, H-Br, H-I), and water (H-OH).

More Related